The role of DNA polymerase I, II and III in the replication of the bacteriocinogenic factor Clo DF13

Summary The replication of the bacteriocinogenic factor Clo DF13 was studied in Escherichia coli mutants which lack either DNA polymerase I (polA1 and resA1 mutants), DNA polymerase II (polB1 mutant) or DNA polymerase III (dnaE mutant). DNA polymerase I is required for Clo DF13 replication. The Clo DF13 factor, however, can be maintained in a strain carrying the polA107 mutation and thus lacking the 53 exonucleolytic activity of DNA polymerase I. DNA polymerase II is not required for transfer replication and maintenance of the Clo DF13 plasmid. In the temperature sensitive dnaE mutant, Clo DF13 can replicate at the nonpermissive temperature during the first two hours after the temperature shift from 30°C to 43°C. During this period DNA polymerase III seems not to be essential for Clo DF13 replication.     

Increased spontaneous mutation rates in mutants of E. coli with altered DNA polymerase III

Summary Two temperature-sensitive mutants in dnaE, the structural gene for DNA polymerase III of Escherichia coli, show increased spontaneous mutation rates at permissive temperatures. Studies of the reversion of well-characterized trpA mutations in dnaE strains show that the mutagenic effect of altered DNA polymerase III applies to several different base substitution events, but not to frameshifts. The results suggest that DNA polymerase III is involved in base-selection during DNA replication.MRC Molecular Genetics Unit     

The use of specialised transducing phages in the amplification of enzyme production

Two types of trp phages have been used as model systems to investigate ways of optimising the expression of bacterial genes from transducing phage genomes.Excellent yields of trp enzymes were achieved by infecting a trpR^– host with Q ^– or Q ^– Q ^– S ^– derivatives of trpAM1, which expresses its trp genese exclusively from the trp promoter. The five trp geneproducts constituted more than 50% of the total soluble protein of infected cells under these conditions, and an even higher proportion of the protein synthesized after infection. In a trpR ⁺ host, phage DNA replication was easily able to override tryptophan-mediated repression by titration of the trp repressor protein. N ^– derivatives of trp phages carrying the trp promoter were equally productive, while having the advantage of being much simpler to construct and propagate.     

Expression of the tryptophan operon in merodiploids of Escherichia coli. I. Gene dosage, gene position and marker effects

Summary Under conditions of derepression,Escherichia coli K12 strains diploid for thetrp operon specify more than twice as much enzyme as a haploid. The disproportionate increase probably occurs because episomally carriedtrp genes tend to specify more enzyme than do chromosomal genes.Operons harboring the nonsense mutationtrpA2 or the missense mutationtrpBYS-101 specify less protein than do wild-type operons. This effect varies with operon location in the case oftrpBYS-101.In a homozygoustrp merodiploid A46/F A46 reversion totrp ⁺ occurs three times as frequently in episomal DNA as in chromosomal DNA. Thus, if the chromosome: Ftrp episome ratio inE. coli is one, as demonstrated by Helinski and co-workers, the rate of gene expression and the rate of mutation can vary and depends upon the location of the DNA within the cell.Supported by Grant AM-12150 from the National Institutes of Health. Journal Paper No. 3973 of Purdue Agricultural Experiment Station.     

Replication of E. coli duplex DNA in vitro

Summary An E. coli lysate after being gently washed to remove soluble components, supports replicative DNA synthesis, if soluble proteins and the deoxyribonucleotide triphosphates are added. This DNA synthesis is dependent on ATP and on the presence of the gene products of the dnaB, dnaG, and polC (DNA polymerase III) genes. It continues at the replication forks preformed in vivo and Okazaki fragments are intermediate products of the reaction.Two different methods were used to prepare the washed DNA containing fraction. The one method involves washing of a cell lysate situated on a dialysis membrane. The other method involves DNAase treatment of a lysate and sedimentation of the degraded DNA through a glycerol gradient. Both washed preparations contain not only the DNA and the replication forks but also functional amounts of DNA polymerase III and of the dnaB gene product. Other factors, that are essential for replicative DNA synthesis, including the dnaG gene product, are washed out of the DNA containing preparations and the system is reconstituted by readdition of the soluble proteins.     

Transposition of DNA inserted into deletions of the Tn5 kanamycin resistance element

Summary Tn5-trp hybrid transposons have been constructed by insertion of a trpPOED Hind III fragment into an in vivo Tn5 internal deletion mutant or by substitution of trp for the internal Tn5 Hind III fragment. These hybrids are called, respectively, Tn409 and Tn410. Both Tn409 and Tn410 will transpose into in the presence of a complementing Tn5 element. In the absence of a wild Tn5, lysogens carrying R1162::Tn409 and R1162::Tn410 plasmids will yield trp phages at less than six per cent of the complemented frequency. This reduction indicates that Tn409 and Tn410 lack a diffusible transposition function provided by wild Tn5 elements. However, the formation of trp phages without complementation is real. Most of these transducing particles contain Tn409 and Tn410 still linked to the carrier R1162 plasmid. This observation suggests that uncomplemented Tn409 and Tn410 elements mediate the formation of -transposon-plasmid cointegrate structures. Thus, the missing transposition function may be involved in resolving these cointegrate structures to the final ::Tn409 or ::Tn410 product.Abbreviations p.f.u. plaque-forming units - MIC minimal inhibitory concentration - LFT low frequency transducing - HFT high frequency transducing     

SPP1 DNA replicative forms: growth of phage SPP1 in Bacillus subtilis mutants temperature-sensitive in DNA synthesis.

Summary The development of bacteriophages SPP1, and 29 has been studied in several B. subtilis mutants defective in host DNA replication, under non permissive conditions.Several gene products, involved in the synthesis of host DNA, are required for 29 replication, while SPP1 seems to require obly the host DNA polymerase III. In addition both phages are unable to grow in a dna A mutant (ribonucleotide reductase). Taking advantage of the fact that SPP1 DNA is actively replicated in several dna mutants at non-permissive temperature, we have studied the structure of the replicative intermediates of this phage in the absence of interfering host DNA synthesis.Fast sedimenting forms of SPP1 DNA can be isolated from phage infected cells and evidence of covalently joined concatemers has been obtained, suggesting the presence of terminally repeated sequences.     

Involvement of DNA polymerase III in UV-induced mutagenesis of bacteriophage lambda

Summary It has been proposed that the mutation fixation processes stimulated by SOS induction result from an induced infidelity of DNA replication (Radman 1974). The aim of this study was to determine if mutator mutations in the E. coli DNA polymerase III might affect UV-induced mutagenesis.Using a phage mutation assay which can discriminate between targeted and untargeted mutations, we show that the polC74 mutator mutation (Sevastopoulos and Glaser 1977) primarily affects untargeted mutagenesis, which occurs in a recA1 genetic background and is amplified in the recA ⁺ genetic background. The polC74 mutation also increases the UV-induced mutagenesis of the bacterial chromosome. These results suggest that DNA polymerase III is involved in the process of UV-induced mutagenesis in E. coli.     

Decay rates of Escherichia coli trp messenger RNA molecules lacking the normal 5''-terminal sequences.

Summary We have examined the stability in vivo of three mutant species of trp mRNA which differ from wild type in the nature of their 5-termini. These novel mRNA molecules originate from three mutationally generated promoters which lie within trp structural genes: trpE1423 lies near the carboxy-terminal end of trpE, trpD11 lies near the carboxy-terminal end of trpD (McPartland and Somerville, 1976) and trpC2121 lies near the center of trpC. When mRNA synthesis from the wild-type promoter is repressed by tryptophan, these strains still synthesize trp mRNA from their internal promoters at a relatively high efficiency in a constitutive fashion. The trp mRNA thus produced by the mutants lacks various lengths of the wild-type 5-proximal RNA sequence. These shortened trp mRNA molecules decayed exponentially, at about the same rate as that of normal trp mRNA whose synthesis originates at the authentic trp promoter. Chloramphenicol inhibited the degradation of 5-truncated trp mRNA fragments in a manner similar to that observed for wildtype trp mRNA, suggesting that the usual mechanism of mRNA decay is operative. We postulate that the initiation of mRNA decay at or near the 5-end does not require some special nucleotide sequence; rather the 5-proximal protion in general constitutes the target for nucleolytic attack.     

Physical map of a 470 x 10(3) base-pair region flanking the terminus of DNA replication in the Escherichia coli K12 genome

In a dnaC28 mutant population synchronized by temperature shifts, the DNA replication rate after initiation is constant for 32 to 34 minutes at 40.5 °C, and then decreases exponentially with a half-time of two minutes to a residual relative rate of 2 to 3%. The DNA of a dnaC28 strain carrying a prophage Mu in the trp operon was labeled during the period of exponential decrease. After lysis the DNA was digested by EcoRI, HindIII or PstI endonucleases, and fractionated on agarose gels. Fractionated DNA from each track was isolated from gel slices and was digested further by the appropriate second and third enzymes and by a mixture of these enzymes. The resulting double and triple digestion products were separated by electrophoresis and were subjected to a fluorographic analysis. From the data obtained a 470 kb² restriction map of the DNA flanking the Escherichia coli K12 terminus of replication has been deduced.     

Mutational specificity of a proof-reading defective Escherichia coli dnaQ49 mutator

Summary The dnaQ (mutD) gene product which encodes the -subunit of the DNA polymerase III holoenzyme has a central role in controlling the fidelity of DNA replication because both mutD5 and dnaQ49 mutations severely decrease the 3–5 exonucleolytic editing capacity.It is shown in this paper that more than 95% of all anaQ49-induced base pair substitutions are transversions of the types G:C-T:A and A:T-T:A. Not only is this unusual mutational specificity precisely that observed recently for a number of potent carcinogens such as benzo(a) pyrene diolepoxide (BPDE) and aflatoxin B1 (AFB1), which are dependent on the SOS system to mutagenize bacteria, but it is also seen for the constitutively expressed SOS mutator activity in E. coli tif-1 strains as well as for the SOS mutator activity mediated gap filling of apurinic sites. Because the G:C-T:A and A:T-T:A transversions can either result from the insertion of an adenine across from apurinic sites or arise due to the incorporation of syn-adenine opposite a purine base, we postulate that the DNA polymerase III holoenzyme also has a reduced discrimination ability in a dnaQ49 background.The introduction of a lexA (Ind^-) allele, which prevents the expression of SOS functions, led to a significant reduction in the dnaQ49-caused mutator effect.Both, the mutational specificity observed and the partial lexA ⁺ dependence of the mutator effect provoke a reanalysis of the hypothesis that the DNA polymerase III holoenzyme can be converted into the postulated but until now unidentified SOS polymerase.     

Mutagenic DNA repair in Escherichia coli. VIII. Involvement of DNA polymerase III in constitutive and inducible mutagenic repair after ultraviolet and gamma irradiation.

Summary Mutagenic repair in Escherichia coli after ultraviolet (UV) irradiation has previously been shown to require a function of DNA polymerase III. In contrast, no effect of incubating a polC temperature-sensitive strain at 42° has been found after gamma irradiation. Thus at present there is no direct evidence for the involvement of polymerase III in gamma ray mutagenesis. This could, however, merely reflect the stability of the premutational lesion during the period of polymerase III insufficiency such that mutagenic repair is resumed on the plate during subsequent incubation at permissive temperature.It was previously suggested that an inducible factor might interact with polymerase III to enable it to polymerise in an error-prone way in daughter strand gaps opposite non-coding lesions in the template strand. A temperature-resistant revertant (CM 792) of a temperature-sensitive polC strain (CM 731) has been isolated which has properties expected of a strain in which the polymerase III complex is no longer susceptible to the inducible co-factor. Its UV sensitivity, spontaneous mutation rate and mutagenic response to ethyl methanesulphonate are all normal or near normal, also the rates of mutation to prototrophy after gamma irradiation and to streptomycin resistance after UV. These latter mutations are believed to arise through constitutive mutagenic repair at sites in pre-existing DNA. In contrast, the rate of UV-induced mutation to prototrophy due to changes at ochre suppressor loci is greatly depressed and no Weigle-reactivation of bacteriophage T3 is observable; both these effects are believed to result from the action of inducible mutagenic repair in newly-replicated DNA. It is suggested that the 3 to 5 exnnuclease activity of the polymerase III complex in CM 792 may not be susceptible to inhibition by an inducible factor and so continues to remove mismatched bases inserted in newly-replicated DNA opposite damage template sites thus preventing the fixation of errors as mutations.     

Mutants in position 69 of the Trp repressor ofEscherichia coli K12 with altered DNA-binding specificity

Structural analysis by X-ray crystallography has indicated that direct contact occurs between Arg69, the second residue of the first helix of the helix-turn-helix (HTH) motif of the Trp repressor, and guanine in position 9 of the -centred consensustrp operator. We therefore replaced residue 69 of the Trp repressor with Gly, Ile, Leu or Gln and tested the resultant repressor mutants for their binding to synthetic symmetrical -or -centredtrp operator variants, in vivo and in vitro. We present genetic and biochemical evidence that Ile in position 69 of the Trp repressor interacts specifically with thymine in position 9 of the -centredtrp operator. There are also interactions with other bases in positions 8 and 9 of the -centredtrp operator. In vitro, the Trp repressor of mutant RI69 binds to the consensus -centredtrp operator and a similartrp operator variant that carries a T in position 9. In vivo analysis of the interactions of Trp repressor mutant RI69 with symmetrical variants of the -centredtrp operator shows a change in the specificity of binding to a -centred symmetricaltrp operator variant with a gua-nine to thymine substitution in position 5, which corresponds to position 9 of the -centredtrp operator.     

Map position of the replication terminus on the Escherichia coli chromosome

Summary The directions of replication of several prophages integrated with a known orientation in the vicinity of the terminus (tre) of chromosome replication (trp::Mu, min 27; rev integrated within rac, min 31, man::Mu, min 35), have been established by determining the molecular polarity of Okazaki pieces specific to these prophages. The results obtained strongly suggest that the site tre is located between rac and man, an otherwise genetically silent region.     

Human Primpol1: a novel guardian of stalled replication forks

Huang and colleagues identify a human primase-polymerase that is required for stalled replication fork restart and the maintenance of genome integrity.EMBO reports (2013) 14 12, 1104–1112 doi:10.1038/embor.2013.159The successful duplication of genomic DNA during S phase is essential for the proper transmission of genetic information to the next generation of cells. Perturbation of normal DNA replication by extrinsic stimuli or intrinsic stress can result in stalled replication forks, ultimately leading to abnormal chromatin structures and activation of the DNA damage response. On formation of stalled replication forks, many DNA repair and recombination pathway proteins are recruited to resolve the stalled fork and resume proper DNA synthesis. Initiation of replication at sites of stalled forks differs from traditional replication and, therefore, requires specialized proteins to reactivate DNA synthesis. In this issue of EMBO reports, Wan et al [1] introduce human primase-polymerase 1 (hPrimpol1)/CCDC111, a novel factor that is essential for the restart of stalled replication forks. This article is the first, to our knowledge, to ascertain the function of human Primpol enzymes, which were originally identified as members of the archaeao-eukaryotic primase (AEP) family [2].Single-stranded DNA (ssDNA) forms at stalled replication forks because of uncoupling of the DNA helicase from the polymerase, and is coated by replication protein A (RPA) for stabilization and recruitment of proteins involved in DNA repair and restart of replication. To identify novel factors playing important roles in the resolution of stalled replication forks, Wan and colleagues [1] used mass spectrometry to identify RPA-binding partners. Among the proteins identified were those already known to be located at replication forks, including SMARCAL1/HARP, BLM and TIMELESS. In addition they found a novel interactor, the 560aa protein CCDC111. This protein interacts with the carboxyl terminus of RPA1 through its own C-terminal region, and localizes with RPA foci in cells after hydroxyurea or DNA damage induced by ionizing irradiation. Owing to the presence of AEP and zinc-ribbon-like domains at the amino-terminal and C-terminal regions, respectively [2], CCDC111 was predicted to have both primase and polymerase enzymatic activities, which was confirmed with in vitro assays, leading to the name hPrimpol1 for this unique enzyme.The most outstanding discovery in this article is that hPrimpol1 is required for the restart of DNA synthesis from a stalled replication fork (Fig 1). With use of a single DNA fibre assay, knock down of hPrimpol1 had no effect on normal replication-fork progression or the firing of new origins in the presence of replication stress. After removal of replication stress, however, the restart of stalled forks was significantly impaired. Furthermore, the authors observed that hPrimpol1 depletion enhanced the toxicity of replication stress to human cells. Together, these data suggest that hPrimpol1 is a novel guardian protein that ensures the proper re-initiation of DNA replication by control of the repriming and repolymerization of newly synthesized DNA.Open in a separate windowFigure 1The role of hPrimpol1 in stalled replication fork restart. (A) Under normal conditions, the replicative helicase unwinds parental DNA, generating ssDNA that is coated by RPA and serves as a template for leading and lagging strand synthesis. Aside from interacting with RPA bound to the short stretches of ssDNA, the role of hPrimpol1 in normal progression of replication forks is unknown. (B) Following repair of a stalled replication fork, (1) hPrimpol1 rapidly resumes DNA synthesis of long stretches of RPA-coated ssDNA located at the stalled fork site. Later, the leading-strand polymerase (2) or lagging-strand primase and polymerase (3) replace hPrimpol1 to complete replication of genomic DNA. RPA, replication protein A; ssDNA, single-stranded DNA.Eukaryotic DNA replication is initiated at specific sites, called origins, through the help of various proteins, including ORC, CDC6, CDT1 and the MCM helicase complex [3]. On unwinding of the parental duplexed DNA, lagging strand ssDNA is coated by the RPA complex and used as a template for newly synthesized daughter DNA. DNA primase, a type of RNA polymerase, catalyses short RNA primers on the RPA-coated ssDNA that facilitate further DNA synthesis by DNA polymerase. While the use of a short RNA primer is occasionally necessary to restart leading-strand replication, such as in the case of a stalled DNA polymerase, it is primarily utilized in lagging-strand synthesis for the continuous production of Okazaki fragments. The lagging-strand DNA polymerase must efficiently coordinate its action with DNA primase and other replication factors, including DNA helicase and RPA [4]. Cooperation between DNA polymerase and primase is disturbed after DNA damage, ultimately resulting in the collapse of stalled replication forks. Until now, it was believed that DNA primase and DNA polymerase performed separate and catalytically unique functions in replication-fork progression in human cells, but this report provides the first example, to our knowledge, of a single enzyme performing both primase and polymerase functions to restart DNA synthesis at stalled replication forks after DNA damage (Fig 1).… this report provides the first example of a single enzyme performing both primase and polymerase function to restart DNA synthesis at stalled replication forksA stalled replication fork, if not properly resolved, can be extremely detrimental to a cell, causing permanent cell-cycle arrest and, ultimately, death. Therefore, eukaryotic cells have developed many pathways for the identification, repair and restart of stalled forks [5]. RPA recognizes ssDNA at stalled forks and activates the intra-S-phase checkpoint pathway, which involves various signalling proteins, including ATR, ATRIP and CHK1 [6]. This checkpoint pathway halts cell-cycle progression until the stalled forks are properly repaired and restarted. Compared with the recognition and repair of stalled forks, the mechanism of fork restart is relatively elusive. Studies have, however, begun to shed light on this process. For instance, RPA-directed SMARCAL1 has been discovered to be important for restart of DNA replication in bacteria and humans [7]. Together with the identification of hPrimpol1, these findings have helped to expand the knowledge of the mechanism of restarting DNA replication. Furthermore, both reports raise many questions regarding the cooperative mechanism of hPrimpol1 and SMARCAL1 with RPA at stalled forks to ensure genomic stability and proper fork restart [7].First, these findings raise the question of why cells need the specialized hPrimpol1 to restart DNA replication at stalled forks rather than using the already present DNA primase and polymerase. One possibility is that other DNA polymerases are functionally inhibited due to the response of the cell to DNA damage. Although the cells are ready to restart replication, the impaired polymerases might require additional time to recover after DNA damage, necessitating the use of hPrimpol1. In support of this idea, we found that the p12 subunit of DNA polymerase δ is degraded by CRL4^CDT2 E3 ligase after ultraviolet damage [8]. As a result, alternative polymerases, such as hPrimpol1, could compensate for temporarily non-functioning traditional polymerases. A second explanation is that the polymerase and helicase uncoupling after stalling of a fork results in long stretches of ssDNA that are coated with RPA. To restart DNA synthesis, cells must quickly reprime and polymerize large stretches of ssDNA to prevent renewed fork collapse. By its constant interaction with RPA1, hPrimpol1 is present on the ssDNA and can rapidly synthesize the new strand of DNA after the recovery of stalled forks. Third, the authors found that the association of hPrimpol1 with RPA1 is independent of its functional AEP and zinc-ribbon-like domains and occurs in the absence of DNA damage. These results might indicate a role for hPrimpol1 in normal replication fork progression, but further work is necessary to determine whether that is true.The discovery of hPrimpol1 is also important in an evolutionary contextSeveral questions remain. First, what is the fidelity of the polymerase activity? Other specialized polymerases that act at DNA damage sites sometimes have the ability to misincorporate a nucleotide across from a site of damage, for example pol-eta and -zeta [9]. It will be interesting to know whether hPrimpol1 is a high-fidelity polymerase or an error-prone polymerase. Second, is the polymerase only brought into action after fork stalling? If hPrimpol1 is an error-prone polymerase, one could envision other types of DNA damage that can be bypassed by hPrimpol1. Third, is the primase selective for ribonucleotides, or can it also incorporate deoxynucleotides? The requirement of the same domain—AEP—for primase and polymerase activities raises the possibility that NTPs or dNTPs could be used for primase or polymerase activities.The discovery of hPrimpol1 is also important in an evolutionary context. In 2003, an enzyme with catalytic activities like that of hPrimpol1 was discovered in a thermophilic archeaon and in Gram-positive bacteria [10]. This protein had several catalytic activities in vitro, including ATPase, primase and polymerase. In contrast to these Primpol enzymes, those capable of primase and polymerase functions had not been found in higher eukaryotes, which suggested that evolutionary pressures forced a split of these dual-function enzymes. Huang et al''s report suggests, however, that human cells do in fact retain enzymes similar to Primpol. In summary, the role of hPrimpol1 at stalled forks broadens our knowledge of the restart of DNA replication in human cells after fork stalling, allowing for proper duplication of genomic DNA, and provides insight into the evolution of primases in eukaryotes.     

The DNA Pol ϵ stimulatory activity of Mrc1 is modulated by phosphorylation

DNA replication checkpoint (Mec1-Mrc1-Rad53 in budding yeast) is an evolutionarily conserved surveillance system to ensure proper DNA replication and genome stability in all eukaryotes. Compared to its well-known function as a mediator of replication checkpoint, the exact role of Mrc1 as a component of normal replication forks remains relatively unclear. In this study, we provide in vitro biochemical evidence to support that yeast Mrc1 is able to enhance the activity of DNA polymerase ? (Pol ?), the major leading strand replicase. Mrc1 can selectively bind avidly to primer/template DNA bearing a single-stranded region, but not to double-stranded DNA (dsDNA). Mutations of the lysine residues within basic patch 1 (BP1) compromise both DNA binding and polymerase stimulatory activities. Interestingly, Mrc1-3D, a mutant mimicking phosphorylation by the Hog1/MAPK kinase during the osmotic stress response, retains DNA binding but not polymerase stimulation. The stimulatory effect is also abrogated in Mrc1 purified from cells treated with hydroxyurea (HU), which elicits replication checkpoint activation. Taken together with previous findings, these results imply that under unperturbed condition, Mrc1 has a DNA synthesis stimulatory activity, which can be eliminated via Mrc1 phosphorylation in response to replication and/or osmotic stresses.     

Evidence for endonucleolytic cleavage at the 5''-proximal segment of the trp messenger RNA in Escherichia coli.

Summary The 5-proximal trp leader RNA segment (about 5S) decays at 2 to 3 times slower rates than the distal trp mRNA sequence. This has been demonstrated by employing the deletion mutants which lack a large portion of the structural genes but retain the promoter-proximal region of the trp operon. Relative stability of the leader RNA is not merely due to the presence of an untranslatable region in the segment; the internal untranslatable segment of trp mRNA downstream from the nonsense alteration site of a double mutant trpAD28·trpE9758 decays as fast as the normal trp mRNA sequence. These results suggest that the trp mRNA is endonucleolytically cleaved to yield the small 5-proximal leader RNA segment before the distal mRNA decays and that the leader RNA sequence is not subject to usual mode of mRNA decay in the 5 to 3 direction.